@article{6d36682af05d4536aef192dffbb737b4,
title = "New Evidence for Wet Accretion of Inner Solar System Planetesimals from Meteorites Chelyabinsk and Benenitra",
abstract = "We investigated the hydrogen isotopic compositions and water contents of pyroxenes in two recent ordinary chondrite falls, namely, Chelyabinsk (2013 fall) and Benenitra (2018 fall), and compared them to three ordinary chondrite Antarctic finds, namely, Graves Nunataks GRA 06179, Larkman Nunatak LAR 12241, and Dominion Range DOM 10035. The pyroxene minerals in Benenitra and Chelyabinsk are hydrated (∼0.018–0.087 wt.% H2O) and show D-poor isotopic signatures (δDSMOW from −444 to −49). On the contrary, the ordinary chondrite finds exhibit evidence of terrestrial contamination with elevated water contents (∼0.039–0.174 wt.%) and δDSMOW values (from −199 to −14). We evaluated several small parent-body processes that are likely to alter the measured compositions in Benenitra and Chelyabinsk and inferred that water loss in S-type planetesimals is minimal during thermal metamorphism. Benenitra and Chelyabinsk hydrogen compositions reflect a mixed component of D-poor nebular hydrogen and water from the D-rich mesostases. A total of 45%–95% of water in the minerals characterized by low δDSMOW values was contributed by nebular hydrogen. S-type asteroids dominantly composed of nominally anhydrous minerals can hold 254–518 ppm of water. Addition of a nebular water component to nominally dry inner solar system bodies during accretion suggests a reduced need of volatile delivery to the terrestrial planets during late accretion.",
author = "Ziliang Jin and Maitrayee Bose and Tim Lichtenberg and Mulders, {Gijs D.}",
note = "Funding Information: We thank Philipp Heck at the Field Museum for providing fresh fragments of ordinary chondrite falls, Johnson Space Center for providing thin sections of ordinary chondrite finds, and the Smithsonian Institution and Kathryn M. Kumamoto at Stanford University for the standard samples. We would like to profusely thank the anonymous reviewers for providing constructive comments and suggestions that helped improve the manuscript. Axel Wittmann and Richard L. Hervig (NSF EAR grant 1819550) are thanked for their assistance with electron probe and IMS 6f operations at ASU. Z.J. was funded by the startup funds from the State Key lab of Lunar and Planetary Science of Macao University of Science and Technology. M.B. was funded by her startup funds from ASU for the analytical work. T.L. was supported by a grant from the Simons Foundation (SCOL award No. 611576). G.D. M. acknowledges support from ANID—Millennium Science Initiative—ICN12_009. This material is based on work supported by the National Aeronautics and Space Administration under agreement No. 80NSSC21K0593 for the program “Alien Earths.” The results reported herein benefitted from collaborations and/or information exchange within NASAʼs Nexus for Exoplanet System Science (NExSS) research coordination network sponsored by NASAʼs Science Mission Directorate. Publisher Copyright: {\textcopyright} 2022. The Author(s). Published by the American Astronomical Society.",
year = "2021",
month = dec,
doi = "10.3847/PSJ/ac3d86",
language = "English",
volume = "2",
journal = "Planetary Science Journal",
issn = "2632-3338",
publisher = "IOP Publishing Ltd.",
number = "6",
}